-
1 total critical load
Англо-русский словарь нормативно-технической терминологии > total critical load
-
2 total critical load
1. суммарная критическая нагрузка (при которой алмазная коронка начинает внедряться в породу)
2. предельная нагрузка (выше которой алмазы разрушаются)Большой англо-русский и русско-английский словарь > total critical load
-
3 total critical load
* * *Англо-русский словарь нефтегазовой промышленности > total critical load
-
4 total critical load
Нефть: предельная нагрузка (выше которой алмазы разрушаются), суммарная критическая нагрузка (при которой алмазная коронка начинает внедряться в породу) -
5 total critical load
суммарная критическая нагрузка (при которой алмазная коронка начинает внедряться в породу); предельная на_ грузка (выше которой алмазы раз рушатся).English-Russian dictionary of terms for geological exploration drilling > total critical load
-
6 total critical pressure
Англо-русский словарь нормативно-технической терминологии > total critical pressure
-
7 total critical pressure
см. total critical load.English-Russian dictionary of terms for geological exploration drilling > total critical pressure
-
8 load
1. груз; нагрузка; загрузка || грузить; нагружать; загружать2. заряд; забойка ( скважинного заряда водой или буровым раствором) || заряжать3. pl. отдельные блоки передвижного оборудования— bit load— net load
* * *
нагрузка; загрузка
* * *
1. нагрузка, напряжение; блок ( оборудования)2. заряд3. грузить, нагружать; заряжать
* * *
1. мощность2. нагрузка; заряжать; загружать программу (компьют.)
* * *
1) нагрузка; загрузка; груз || грузить; наливать ( нефть в танкеры)2) заряд || заряжать3) забойка ()4) блок ( оборудования)•- balancing load
- beam load
- bearing load
- bit load
- bottom load
- breaking load
- buckling load
- cable load
- calculated load
- casing load
- collapse load
- collapsing load
- compression load
- concentrated load
- continuous load
- cracking load
- crashing load
- cyclic load
- damaging load
- dead load
- dead load of derrick
- dead-line load
- derrick collapsing load
- destructive load
- dynamic load
- eccentric bit load
- effective wind load
- emergency load
- engineering service load
- equivalent load on derrick
- explosive load
- even load
- failure load
- fatigue load
- filter load
- full load
- gust load
- hoisting load
- hole load
- hook load
- impact load
- impact allowance load
- imposed load
- impulsive load
- intermittent load
- knife-edge load
- light load
- line load
- linear load
- live load
- maximum load
- maximum permissible load
- normal load
- off-center load
- operational load
- overburden load
- permanent load
- pipe setback load
- point load
- polished rod load
- pulsating load
- repeated load
- resultant load
- running line end load
- safe load
- safe bearing load
- sedimentary load
- service load
- shock load
- single-point load
- steady load
- strainer load
- sucker-rod load
- sustained load
- tensile load
- test failure load
- thrust load
- tilting load
- torque load
- torsional load
- total load
- total bit load
- total critical load
- transient shock wave load
- ultimate load
- unbalanced load
- uncompensated load
- uniform load
- uniformly distributed load
- unit load
- unit bit load
- unit wind load
- useful load
- variable load
- varying load
- vibratory shock load
- wellhead landing load
- working load
- yield load* * *• блок• забойка• наливать -
9 load
1) груз; нагрузка2) транспортируемые наносы, расход наносов3) мн. ч. нагрузки4) грузить; нагружать•load on axle — давление на ось; нагрузка оси
load per unit length — погонная равномерная нагрузка; погонная нагрузка
load testing of structures — испытание сооружений нагрузкой, нагружением
load uniformly distributed over span — нагрузка, равномерно распределённая по пролёту
- additional load - allowable load - alternate load - alternating load - antisymmetrical loads - apex load - application of load - applied load - assumed load - asymmetric load - axial load - axle load - basic load - bearable load - bed load - bending load - bracket load - brake load - breaking load - buckling load - ceiling load - centre-point load - centric load - centrifugal load - changing load - collapse load - column load - combination of load - combined load - compressive load - concentrated load - concentrated moving load - continuous load - cooling load - cracking load - crane load - crippling load - critical load - crushing load - dangerous load - dead load - debris bed load - design load - distributed load - distribution of load - dynamic load - dynamical load - eccentric load - edge load - elastic-limit load - emergency load - equalization of load at conveyer pulleys - equalization of load at hoisting drums - Euler's crippling load - even load - evenly distributed load - excess load - excessive load - failure load - fictitious load - filter load - fixed load - fluctuating load - follower load - fractional load - full load - gradually applied load - gravity load - gust load - heaped load - heating load - hydrodynamic load - hydrostatic load - ice load - imaginary load - impact load - impulsive load - instantaneous load - intermittent load - irregularly distributed load - lateral load - limit load - linear load - linearly varying load - line-distributed load - live load - maximum load - midspan load - minimum load - miscellaneous load - mobile load - moisture load - momentary load - movable load - moving load - near-ultimate load - net load - nominal load - non-central load - off-design load - organic load - out-of-balance load - panel load - parabolic load - pay load - payable load - peak load - periodically applied load - permanent load - permanently acting load - permissible load - pick-up load - point load - pollutant load - pollutional load - pressure load - proof load - pulsating load - punch load - quiescent load - racking load - rated load - repeated load - reversal load - reversed load - rolling load - safe load - salt load - seismic load - service load - severe load - sewage load - shear lock load - shock load - specified load - static load - statical load - steady load - stiffness test load - sudden load - suddenly applied load - super-load - superimposed load - suspended load - sustained load - symmetrical loads - terminal load - test load - third point load - tilting load - torsional load - total load - transferred load - transient load - transverse load - travelling load - trial load - ultimate load - unbalanced load - uniform load - unit load - unsafe load - useful load - varying load - vibratory load - waste load - water load - weight load - wheel load - wind loadto load in bulk — грузить насыпью, навалом
* * *1. груз; нагрузка || нагружать, загружать2. наносы ( транспортируемые потоком)load applied in increments — нагрузка, прилагаемая отдельными ступенями [приращениями]
loads applied to the formwork — нагрузки, действующие на опалубку
loads equidistant from midspan — сосредоточенные нагрузки, равноотстоящие от середины пролёта ( балки)
loads in excess of the concrete capacity — нагрузки, превышающие несущую способность бетона
load normal to the surface — нагрузка, нормальная к поверхности
load on the member — нагрузка, действующая на элемент конструкции
- load of streamunder load — под нагрузкой; в нагруженном состоянии
- load of uncertain magnitude
- abnormal load
- accepted load
- accidental load
- adjustable load
- air conditioning load
- allowable load
- allowable axial load
- allowable pile-bearing load
- alternating load
- antisymmetric load
- applied load
- arbitrary load
- area load
- assumed load
- asymmetrically-placed loads
- avalanche load
- average load
- axial load
- axial compression load
- axially symmetric load
- axial tension load
- axisymmetrical load
- axle load
- balanced load
- basic load
- bearing load
- bed load
- bending load
- biaxial load
- blast load
- breaking load
- bucket load
- buckling load
- central point load
- changing load
- characteristic load
- characteristic dead load
- characteristic live load
- climatic load
- collapse load
- collision load
- combined load
- combined axial and bending loads
- combined torsion-shear-flexure loads
- compression load
- concentrated load
- connected load
- construction loads
- continuous load
- cooling load
- crippling load
- critical load
- critical buckling load
- dead load
- derailment load
- design load
- design snow load
- design ultimate load
- distributed load
- dummy load
- dummy unit load
- dust load
- dynamic load
- earthquake load
- eccentric load
- eccentric and inclined load
- equivalent load
- erection load
- Euler load
- excess load
- explosion load
- factored load
- failure load
- fictitious design load
- fictitious load
- fire load
- fluctuating load
- fracture load
- frictional load
- front axle load
- gravity load
- gross cooling load
- ground snow load
- gust load
- heat load
- heating load
- highway loads
- highway bridge loads
- horizontal load
- humidification load
- hydrostatic load
- ice load
- imaginary load
- immission load
- impact load
- imposed load
- impulsive load
- inertial loads
- intended load
- joint load
- latent heat load
- lateral load
- lateral soil load
- limit load
- linear load
- linearly distributed load
- live load
- local load
- long duration load
- longitudinal load
- maximum load of pollution
- maximum rated load
- maximum safe load
- maximum safe working load
- maximum safe working load at the various radii
- minimum design dead loads
- minimum design live loads
- mobile load
- moving load
- moving uniform load
- near-ultimate load
- nominal uniformly distributed load
- nominal vertical wind load
- nonaxial load
- nonuniform load
- nonuniformly distributed loads
- nuisance load
- occupancy load
- off-center load
- off-peak load
- one-sided load
- on-peak load
- operating load
- panel load
- part load
- pattern load
- peak load
- permanent load
- permissible load
- point load
- pollution load
- ponding load
- primary live load
- proof load
- pulsating load
- radial load
- railway load
- rain load
- rarely occurring load
- rated load
- real load
- recommended load
- refrigerating load
- repeated load
- required design load
- residual load
- roof loads
- rupture load
- safe leg load
- safe working load
- seismic load
- sensible heat load
- service load
- service dead load
- service live load
- sewage load on treatment plant
- sewage load on water body
- shearing load
- shock load
- short duration load
- single load
- sinusoidal loads
- snow load
- snow load on a horizontal surface
- space load
- specified characteristic load
- static load
- static imposed load
- structural design load
- sudden load
- superimposed load
- superimposed dead load
- suspended load
- sustained load
- symmetrical load
- tensile load
- test load
- tipping load
- torsional load
- traffic load
- transmission heat load
- transverse load
- treating load
- trial load
- triaxial load
- twisting load
- ultimate load
- unbalanced load
- uniaxial loads
- uniform load
- uniform load on a beam overhang
- uniform load over a part of the span
- uniform load over part of the span
- uniform load over the full length of a beam with overhangs
- uniform load over the full length of a cantilever
- uniform load over the full span
- uniformly distributed load
- unit load
- unit generalized load
- unsymmetrical load
- useful cooling load
- variable load
- vehicle load
- vehicular live loads
- ventilation heat load
- vertical load
- wash load
- wave load
- wheel load
- wind load
- wind load on a truss
- working load -
10 load
нагрузка; груз; загрузка; заряд; тяжесть; ноша; загруженность (количество работы); закладка (заготовки в станок); pl. гружёные вагонетки; II грузить; нагружать; загружать; закладывать (деталь в приспособление); заряжать- load at first crack - load carrying capacity - load-carrying covering - load-carrying skin - load curve - load-deflection curve - load deflection of tyre - load-deformation curve - load diversity - load due to own weight - load due to snow - load due to wind - load extension curve - load increment - load-inflation table - load limit - load on axle - load out - load peak - load per unit - load per unit length - load rate - load-supporting ability of ground - load-strain diagram - load tension - load test - load testing of structures - load-time diagram - load to collapse - load-transfer device - load uniformly distributed over span - load-up - load-up condition - at no load - acting load - active load - actual load - apex load - artificial load - assumed load - asymmetric load - attach a sling to the load - bulky load - cable load - capacitive load - capacity load - carousel load - carry a load - centre-point load - centric load - centrifugal load - cantilever load - constant power load - constant torque load - dead-line load - drawbar load - dynamical load - elastic-limit load - emergency load - endurance limit load - equalization of load at conveyer pulleys - equalization of load at hoisting drums - equivalent load - extra load - fail under a load - fail under an impact load - failure load - fictitious load - filter load - frictional load - gravity load - gripper load - heaped load - heating load - heavy load - high friction load - high inertial load - hydrodynamic load - hydrostatic load - ice load - lateral load - locking load - machine load - maximum load - maximum useful load on table - midspan load - minimum load - miscellaneous load - mobile load - momentary load - most efficient load - movable load - moving load - multiaxial loads - near-ultimate load - net load - no-load - nominal load - non-central load - noncutting load - normal load - oblique load - off-center load - off-design load - operate at no-load - operating load - optimally load - optimum work load - oscillating load - out-of-balance load - outer load - outer ring load - overhauling load - overhung load - over-tolerance load - palletized work load - panel load - parabolic load - part load - pay load - paying load - peak load - permanent load - permanently acting load - permissible load - perpendicular load - pick-up load - piezoelectric load - point load - pollutant load - pollutional load - potential order load - predetermined maximum cutting load - pressure load - production load - proof load - proportional limit load - pulling load - pulsating load - punch load - quiescent load - racking load - radial load - rapidly moving load - rated load - rated load capacity - react a load - reactive load - release the load - repeated load - resist load - return load - reversal load - reversed load - rolling load - roof load - rotating inner ring load - rotating outer ring load - safe load - safe bearing load - service load - severe load - shear load - shear lock load - shearing load - shock load - side load - sightseers loading onto a bus - single load - snow load - specific tooth load - specified load - specified rated load - split load - stated load - static load - statical load - stationary load - steady load - steady-state load - steering axle load - stiffness test load - stylus load - sucker-rod load - sudden load - suddenly applied load - super-load - superimposed load - sustained load - surface load - symmetrical loads - take up the load - tangential load - target load - tensile load - tension load - terminal load - test load - test scale load - thrust load - tilting load - tooth load - torque load - torsional load - total load - towed load - traction load - tractional load - traffic load - transferred load - transient load - transmitted load - transport a load - transverse load - travelling load - trial load - ultimate load - unbalanced load - under load - uniform load - uniformly distributed load - unit load - unsafe load - useful load - variable load - varying load - vibrational load - vibratory load - waste load - water load - way-supported loads - weight load - wheel load - wide load - wind load - working load - zero load -
11 суммарная критическая нагрузка
Большой англо-русский и русско-английский словарь > суммарная критическая нагрузка
-
12 parallel UPS system
параллельная система ИБП
-
[Интент]Parallel Operation: The system shall have the option to install up to four (4) UPSs in parallel configuration for redundancy or capacity.
1. The parallel UPS system shall be of the same design, voltage, and frequency. UPS modules of different size ratings shall be permitted to be paralleled together for purposes of increased capacity or UPS module redundancy. The UPSs in the parallel configuration shall not be required to have the same load capacity rating.
2. Parallel Capacity: With N+0 system-level redundancy, up to 2MW of load can be supported by the system.
3. Parallel Redundancy: With N+1 system-level redundancy, up to 1.5MW of load can be supported by the system, and only the UPS being replaced must be isolated from the source (bypass operation is not required for the entire system during the UPS replacement procedure).
4. Output control: A load sharing circuit shall be incorporated into the parallel control circuits to ensure that under no-load conditions, no circulating current exists between modules. This feature also allows each UPS to share equal amounts of the total critical load bus. The output voltage, output frequency, output phase angle, and output impedance of each module shall operate in uniformity to ensure correct load sharing. This control function shall not require any additional footprint and shall be an integral function of each UPS. The static bypass switches shall be connected in parallel.
5. Parallel System Controls: To avoid single points of failure, the UPS system shall have no single dedicated control system designed to control the operation of the parallel UPS system. Control of and direction of parallel UPSs shall take place via a master/slave relationship, where the first UPS to receive logic power asserts itself as a master. In the event of a master failure, a slave UPS shall take the role of master and assume the responsibility of the previous master UPS. Regardless of which UPS is master or slave, user changes to the system status, such as request for bypass, can be done from any UPS connected to the bus and all UPS on the bus shall transfer in simultaneously.
6. Communication: Communication between modules shall be connected so that the removal of any single cable shall not jeopardize the integrity of the parallel communication system. Load sharing communications shall be galvanically isolated for purposes of fault tolerance between UPS modules. A UPS module's influence over load sharing shall be inhibited in any mode where the UPS inverter is not supporting its output bus. Transfers to and from bypass can be initiated from any online UPS in the system.
7. Display: Each UPS multi-color LCD touch screen user interface shall be capable of using an active touch screen mimic bus to show the quantity of UPS(s) connected to the critical bus, as well as the general status of each UPS, such as circuit breaker status information. Any touchscreen display shall support the configuration of the [entire parallel] system and shall provide event and alarm data for all UPSs in the parallel configuration. A Virtual Display Application shall be available for download to the customer’s computer and shalll support remote monitoring of a complete system with up to 4 UPSs in parallel.
8. Battery runtime: Each UPS must have its own battery solution. The battery solution for the entire system can be a combination of standard and third-party batteries, but each UPS must use only one battery solution – either standard or third-party batteries.
9. Switchgear: A custom switchgear option shall be required for parallel operation.
[Schneider Electric]Тематики
EN
Англо-русский словарь нормативно-технической терминологии > parallel UPS system
-
13 pressure
давление; пластовое давление; усилие; напор; напряжение; сжатиеpressure above the atmospheric — давление выше атмосферного; манометрическое [избыточное] давление, сверхдавление
pressure applied at the surface — давление, создаваемое на устье скважины
pressure at the economic level — давление, определяемое экономичностью разработки
pressure on the bit — давление на долото, нагрузка на долото
* * *
давление; пластовое давление
* * *
1) давление2) интенсивная эксплуатация, переэксплуатация ( природных ресурсов) скважины•pressure applied at surface — давление, создаваемое на устье скважины;
pressure at economic level — давление, определяемое экономичностью обработки;
pressure at well bore — забойное давление;
pressure in place — давление в залежи;
pressure in reservoir — давление в залежи;
pressure on bit — давление на долото, нагрузка на долото;
pressure on intake side of pump — давление на входе в насос;
pressure per diamond — удельное давление на один алмаз;
to keep up pressure — поддерживать давление;
to maintain pressure — поддерживать давление;
to offset formation pressure — создавать противодавление на пласт;
- abandonment pressureto pressure up — проверять плотность соединений перед кислотной обработкой; опрессовывать
- abnormal formation pressure
- abnormal gas pressure
- abnormal pore pressure
- abnormal reservoir pressure
- abnormal rock pressure
- abnormal well pressure
- abnormally high pressure
- above bubble point pressure
- absolute formation pressure
- absolute reservoir pressure
- absolute wellhead pressure
- annular friction pressure
- annulus pressure
- anomalously high pore pressure
- applied pressure
- areal average pressure
- atmospheric pressure
- available pressure
- average flowing pressure
- average reservoir pressure
- average unit pressure
- back pressure
- barometric pressure
- bit pressure
- boost pressure
- borehole pressure
- bottom-loading pressure
- bottomhole pressure
- bottomhole circulating pressure
- bottomhole differential pressure
- bottomhole flowing pressure
- bottomhole shut-in pressure
- breakdown pressure
- bubble-point pressure
- bubble-point pressure of reservoir oil
- bursting pressure
- casing pressure
- casing-burst pressure
- casing-head pressure
- charging pressure
- chip hold-down pressure
- circulating pressure
- circulating fluid pressure
- circulation pressure
- closed pressure
- closed-in pressure
- closed-in bottomhole pressure
- collapse pressure
- collapsing pressure
- compression pressure
- compressor discharge pressure
- compressor outlet pressure
- contact pressure
- critical pressure
- current pressure
- delivery pressure
- detonation pressure
- diamond pressure
- differential pressure
- discharge pressure
- discharge pressure at pump
- discharge line pressure
- displacement pressure
- down pressure
- drilling pressure
- drilling agent pressure
- drilling bit-nozzle pressure
- drilling mud pressure
- drilling mud bottomhole pressure
- drilling mud column pressure
- drilling mud head pressure
- driving pressure
- edge water pressure
- effective pressure
- equilibrium formation pressure
- equilibrium reservoir pressure
- excess pressure
- explosion pressure
- external boundary pressure
- feed pressure
- field pressure
- final bottomhole pressure
- final flowing pressure
- final formation pressure
- final hydrostatic pressure
- final hydrostatic drilling mud pressure
- final inflow pressure
- final reservoir pressure
- final residual reservoir pressure
- final shut-in pressure
- final shut-in bottomhole pressure
- final squeeze cementing pressure
- final tubing pressure
- flooding pressure
- flow pressure
- flow line pressure
- flowing pressure
- flowing bottomhole pressure
- flowing casing pressure
- flowing reservoir pressure
- flowing surface pressure
- flowing tubing pressure
- flowing tubing head pressure
- flowing wellhead pressure
- flowing wellhead annulus pressure
- fluid pressure
- fluid-displacement pressure
- formation pressure
- formation breakdown pressure
- formation fracture pressure
- forward pressure
- fractional pressure
- fracture pressure
- fracture opening pressure
- fracture widening pressure
- fracturing pressure
- full well pressure
- gage pressure
- gas pressure
- gas cap pressure
- gas inrush pressure
- gas pipeline pressure
- gas reservoir pressure
- gaslift differential pressure
- geostatic pressure
- ground pressure
- high pressure
- hydraulic pressure
- hydraulic fracturing pressure
- hydrofracturing pressure
- hydrostatic pressure
- hydrostatic bottomhole pressure
- hydrostatic kill pressure
- inflation pressure
- initial bottomhole pressure
- initial closed-in bottomhole pressure
- initial flowing pressure
- initial flowing wellhead pressure
- initial formation pressure
- initial hydrofracturing pressure
- initial hydrostatic drilling mud pressure
- initial inflow pressure
- initial reservoir pressure
- initial shut-in pressure
- initial shut-in bottomhole pressure
- initial vapor pressure
- injection pressure
- injection gas pressure at surface
- inlet pressure
- instantaneous shut-in pressure
- intake pressure
- intake well head pressure
- interstitial fluid pressure
- jack pressure
- jacking pressure
- kickoff pressure
- lateral pressure
- leak-off pressure
- line pressure
- liquid pressure
- live pressure
- log-derived pore pressure
- low pressure
- low-frequency pressure
- low-injection pressure
- manifold pressure
- maximum allowable pressure
- maximum allowable casing pressure
- maximum allowable surface pressure
- maximum allowable working pressure
- maximum flowing pressure
- maximum initial field pressure
- maximum initial reservoir pressure
- maximum surface pressure
- maximum top pressure
- maximum tubing pressure
- maximum wellhead pressure
- mean reservoir pressure
- medium pressure
- middle pressure
- mixing pressure
- mud pump pressure
- mud pump shock pressure
- negative pressure
- normal pressure
- normal pore pressure
- nozzle pressure
- oil pressure
- oil column pressure
- oil displacement pressure
- oil vapor pressure
- omnidirectional pressure
- open-flow pressure
- open-hole pressure
- original average reservoir pressure
- original bubble-point pressure
- original reservoir pressure
- original reservoir gas pressure
- oscillatory pressure
- outlet pressure
- overburden pressure
- pipe collapsing pressure
- pipeline pressure
- pipeline admission pressure
- piping pressure
- pore pressure
- pore fluid pressure
- priming pressure
- producing pressure
- producing bottomhole pressure
- propping pressure
- pump pressure
- pump discharge pressure
- pump inlet pressure
- pump intake pressure
- pump-in pressure
- pumping-out pressure
- Reid vapor pressure
- relief pressure
- replacement pressure
- reservoir pressure
- reservoir pressure as of date of appraisal
- reservoir pressure reduced to a plane
- reservoir back pressure
- return pressure
- rock pressure
- roof pressure
- sampling pressure
- sand pressure
- sand-face injection pressure
- saturation pressure
- saturation pressure of reservoir fluid
- seam pressure
- separation pressure
- separator pressure
- shut-in pressure
- shut-in bottomhole pressure
- shut-in casing pressure
- shut-in drill pipe pressure
- shut-in formation pressure
- shut-in reservoir pressure
- shut-in tubing pressure
- shut-in wellhead pressure
- shut-in wellhead annulus pressure
- side pressure
- slush pump pressure
- squeeze pressure
- standard pressure
- standpipe pressure
- static pressure
- static bottomhole pressure
- static reservoir pressure
- static wellhead annulus pressure
- steady-state reservoir pressure
- stone pressure
- stream pressure
- subsurface pressure
- suction pressure
- suction end pressure
- surface pressure
- surface mud pressure
- surface squeeze pressure
- surplus pressure
- terminal pressure
- terminal pipeline pressure
- test pressure
- top-hole pressure
- top-hole flow pressure
- top-hole gaslift pressure
- total pressure
- total bit pressure
- total critical pressure
- tubing pressure
- unbalanced pressure
- underground pressure
- undisturbed formation pressure
- unit pressure
- unit ground pressure
- unsteady-state reservoir pressure
- uplift pressure
- uplift pressure on bottom
- velocity pressure
- virgin pressure
- virgin formation pressure
- water pressure
- water hammer pressure
- water inrush pressure
- weighted average reservoir pressure
- well pressure
- well flowing pressure
- wellbore pressure
- wellhead pressure
- wellhead annulus casing pressure
- wellhead back pressure
- wellhead flowing pressure
- wind pressure
- working pressure* * *• усилиеАнгло-русский словарь нефтегазовой промышленности > pressure
-
14 stress
1) (механическое) напряжение; напряжённое состояние; условное напряжение2) нагрузка, усилие3) гидроудар4) воздействие5) нагрузка на единицу площади, интенсивность нагрузки, удельная нагрузка•- actual stress - admissible stress - advancing load stress - allowable stress - alternate stress - applied stress - arch stress - axial stress - bar stress - basic stress - bearing stress - belt stresses - bending stress - blow stress - bond stress - braking stress - breaking stress - calculated stress - chord stress - circular symmetrical stress - combined stress - completely reversed stresses - complex stress - compressive stress - compressive stress in bending - concrete stress - constant stress - cooling stress - couple stress - crack stress - crackforming stress - crippling stress - critical stress - critical compressive stress - cross-bending stress - cyclical stresses - dead stress - dead-load stress - design stress - direct stress - discontinuity stress - downward stress - dynamic stress - ecological stress - edge stress - effective stress - elastic stress - engineering stress - erection stress - external stress - fabrication stress - failing stress - fatigue stress - fatigue limit stress - fibre stress - final stress - flexural stress - floor stress - fluctuating stresses - friction-induced stress - functional stress - gravity stress - ground stress - handling stress - heat stress - hoist stresses - hoop stress - horizontal stress - impact stress - indirect stress - induced stress - inherent stresses - initial stress - intermediate stress - internal stress - jacking stress - lateral stress - limiting maximum stress - linear stress - live load stress - load stress - local stresses - locked-up stresses - longitudinal stress - mechanical stress - net stress - neutral stress - normal stress - operating stress - operational stress - permissible stress - plane stress - point-load stress - primary stress - principal stresses - proof stress - radial stress - reinforcement stresses - relaxation of stresses - repeated stresses - residual stress - reverse stress - rupture stress - safe stress - secondary stress - shearing stress - shock stress - simple stress - snow load stress - specific stress - static stress - subsidiary stress - surface stress - sustained stress - sway stress - tangential stress - temperature stress - tensile stress - thermal stress - thermal stress on structure - three-dimensional stress - time-dependant stress - torsional stress - total stress - transverse stress - true stress - twisting stress - ultimate stress - uniaxial stress - unit stress - unsafe stress - varying stress - vibratory stress - volumetric stress - water stress - wave stress - welding stress - wheel-load stress - wind stress - working stress - yield stress - yield point stressstress due to prestress — усилие ( в бетоне), вызванное предварительным напряжением
* * *1. (внутреннее) усилие, внутренняя сила2. (механическое) напряжение3. нагрузка на единицу площади, интенсивность нагрузки, удельная нагрузкаstress acting away from the joint — усилие ( в элементе фермы), действующее от узла
stresses arising from bending and axial loading — напряжения, возникающие от поперечного изгиба и действия продольных сил
stress constant across the section — напряжение, постоянное по всему сечению
stress due to prestress — усилие обжатия бетона; напряжение в бетоне, вызванное обжатием
stresses due to wind forces — напряжения от сил ветра, напряжения от ветровой нагрузки
stresses induced by loads — напряжения, вызванные нагрузкой [нагружением] ( в отличие от температурных напряжений)
stress in reinforcement — напряжение [усилие] в арматуре
stresses in truss components [in truss members] — усилия в стержнях [элементах фермы]
stress resolved into two components — напряжение, разложенное на две составляющие
stress varying from point to point — напряжение, меняющееся от точки к точке ( сечения элемента)
- actual stressstresses with the elastic limit — напряжения, не превышающие предела упругости; напряжения в упругой области
- additional stress
- allowable stress
- allowable unit stress
- alternate stress
- anchorage bond stress
- average stress
- axial stress
- bar stress
- bearing unit stress
- bearing stress
- belt stress
- bending stress
- bending failure stress
- biaxial stress
- blow stress
- bond stress
- bottom-chord stress
- boundary stress
- breaking stress
- buckling stress
- calculated stress
- circumferential unit stress
- circumferential stress
- combined stresses
- combined bearing, bending, and shear stresses
- combined shear and bending stress
- compression stress
- compressive stress in bending
- concentrated-load stress
- constant stress
- crack-inducing stress
- crippling stress
- critical stress
- crushing stress
- cycle stress
- dead load stress
- design stress
- development bond stress
- deviation stress
- deviator stress
- direct stress
- drying shrinkage stresses
- dynamic stress
- edge stress
- effective stress
- equivalent stress
- erection stress
- extreme fiber stress
- extreme stress
- failure stress
- fatigue stress
- fiber stress
- final stress
- flexible stress
- floor stress during operation
- floor stress when climbing
- flow stress
- fluctuating stresses
- fracture stress
- freezing stresses
- gravity stress
- handling stresses
- high localized stresses
- hoop stress
- hydrostatic stress
- ideal main stress
- impact stresses
- initial stresses
- intergranular stress
- intermediate principal stress
- jacking stress
- larger principal stress
- limiting stresses permitted in the standard
- linearly varying stresses
- live-load stress
- local stresses
- local bond stress
- longitudinal stress
- main stress
- maximum stress
- maximum allowable stress
- maximum shearing stress
- mean stress
- mean cycle stress
- mean fatigue stress
- membrane stresses
- meridian stress
- negative normal stress
- neutral stress
- normal stress
- octahedral normal stress
- octahedral shear stress
- peak stress
- permissible stress
- plate stresses
- point-load stress
- positive normal stress
- primary stress
- principal stresses
- principal tensile stress
- proof stress
- proof stress at 0.2 percent set
- pulsating stress
- radial stress
- radial shearing stress
- reduced main stress
- reinforcement stress
- repeated stress
- residual stress
- reversed stress
- rupture stress
- safe stress
- secondary stresses
- service stress
- settlement stresses
- shear stress
- shear stresses on oblique planes
- shear buckling stress
- shearing stress
- shrinkage-related stress
- shrinkage stress
- smaller principal stress
- spherical stress
- splitting tensile stress
- static stress
- surface stress
- tangential stress
- temperature stress
- temporary stress
- tensile stress
- tensile stress due to bending
- thermal stress
- timber stresses
- time-dependent stress
- top-chord stress
- torsional stress
- total stress
- transverse bending stress in flange
- true stress
- truss stresses
- truss stresses determined by method of sections
- twisting stress
- ultimate stress
- ultimate shear stress
- ultimate tensile stress
- unit stress
- unit stress produced by design loads
- unrelieved stress
- working stress
- yield stress -
15 flow
1) течение; поток || течь2) сток3) расход, дебит4) растекание; расплыв(ание) || растекаться; расплываться5) пластическая деформация || претерпевать пластическую деформацию6) текучесть7) нефт. фонтанирование || фонтанировать8) нефт. добыча9) подвижность (напр. бетонной смеси)10) технологический маршрут; последовательность операций11) гидр. движение12) непрерывная подача энергии (электрической, тепловой)13) наводнение; затопление; разлив14) отводная труба16) разлив ( лакокрасочного покрытия)17) выпрессовка, грат (в прессовании пластмасс, резины)•to bypass flows — гидр. 1. пропускать строительные расходы по обводному каналу 2. пропускать паводок в обход сооруженияflow of catchment — сток водосбросаflow of control — 1. процесс управления 2. алгоритм управления; поток (команд) управленияflow of ground — пластическая деформация грунта-
adiabatic flow
-
air flow
-
air-mass flow
-
airport traffic flow
-
air-water flow
-
all-gas flow
-
annual flow
-
annular flow
-
annular two-phase flow
-
annular-dispersed flow
-
approach flow
-
artesian flow
-
available flow
-
average annual flow
-
axial flow
-
backward flow
-
back flow
-
base flow
-
bearing form oil flow
-
behind-the-casing flow
-
blade-to-blade flow
-
boiling channel flow
-
boundary layer flow
-
break flow
-
bubble flow
-
bubbly flow
-
bulk flow
-
bypass flow
-
cascade flow
-
channel flow
-
chip flow
-
chugging flow
-
churn-turbulent flow
-
churn flow
-
climbing film flow
-
cocurrent catalyst flow
-
cocurrent flow
-
coherent boiling flow
-
cold flow
-
command-status flow
-
communication flow
-
constant flow
-
continuous flow
-
control flow
-
controlled flow
-
convergent flow
-
coolant flow
-
corkscrewlike flow
-
countercurrent flow
-
critical flow
-
cross flow
-
current flow
-
daily flow
-
data flow
-
decaying swirl flow
-
density-stratified flow
-
design water flow
-
developed flow
-
developed turbulent flow
-
direct surface flow
-
dispersed flow
-
divergent flow
-
diversion flow
-
down flow
-
downstream flow
-
downward flow
-
drainage flow
-
droplet-dispersed flow
-
droplet-free flow
-
dust flow
-
energy flow
-
estimated flow
-
evaporating flow
-
exergy flow
-
exhaust flow
-
failure flow
-
fictitious heat flow
-
filter fluid flow
-
flood flow
-
fluid flow
-
fog flow
-
forced flow
-
forward flow
-
free flow
-
free-surface flow
-
freight flow
-
frictional flow
-
froth flow
-
frozen flow
-
full flow
-
gas flow
-
gas piston flow
-
gas-liquid flow
-
generalized Couette flow
-
glass flow
-
grain-boundary flow
-
gravity flow
-
groundwater flow
-
heat flow
-
high flow
-
high-velocity bypass flow
-
homogeneous flow
-
horizontal flow
-
hydraulically smooth wind flow
-
hydroelectric flow
-
ice flow
-
incident flow
-
incoming flow
-
induced flow
-
information flow
-
ink flow
-
instruction flow
-
insurge flow
-
interconnection tie flow
-
intermittent flow
-
interrupt flow
-
interstitial flow
-
inverse annular flow
-
irrigation return flow
-
irrotational flow
-
isothermal flow
-
Knudsen flow
-
laminar flow
-
lateral flow
-
leakage flow
-
leak flow
-
letdown flow
-
liquid-vapor flow
-
load flow
-
low Reynolds number flow
-
low-velocity flow
-
low-water flow
-
magnetic flow
-
makeup flow
-
mass flow
-
mean flow
-
metered flow
-
mist flow
-
mixed flow
-
molecular flow
-
motion flow
-
mud-and-stone flow
-
multiphase flow
-
natural flow
-
near-bottom flow
-
negative core flow
-
no-load flow
-
noncontinuous flow
-
nonstationary flow
-
nonswirling flow
-
nonuniform flow
-
nozzle flow
-
n-sequential orifice flow
-
open-channel flow
-
outsurge flow
-
oven flow
-
overbank flow
-
peak flow
-
pipe flow
-
piston flow
-
plain-strain flow
-
plastic flow
-
plug flow
-
positive core flow
-
positive flow
-
postcombustion flow
-
potential flow
-
power flow
-
pressure flow
-
primary coolant flow
-
primary flow
-
priority flow
-
process flow
-
pulsating flow
-
pump output flow
-
pump flow
-
radial flow
-
ram air flow
-
reattached flow
-
recirculating flow
-
recirculating turbulent flow
-
recorded flow
-
recycling flow
-
reduced flow
-
reflux flow
-
regulated flow
-
retarded flow
-
return flow
-
reverse core steam flow
-
reverse flow
-
reverse-direction flow
-
ripple flow
-
riser flow
-
river flow
-
rotating flow
-
routed flow
-
seasonal flow
-
seepage flow
-
self-adapting production flow
-
self-aligning production flow
-
semiannular flow
-
separate flow
-
serrated flow
-
servovalve control flow
-
shear flow
-
sheet flow
-
sliding flow
-
slip flow
-
slipless flow
-
slugging flow
-
slug flow
-
smooth flow
-
snow flow
-
soil water flow
-
split flow
-
steady-state flow
-
steady flow
-
steering flow
-
storm flow
-
stratified flow
-
streamline flow
-
streamlined production flow
-
submerged flow
-
subsonic flow
-
subsurface water flow
-
supergeostrophic flow
-
supersonic flow
-
surface-water flow
-
surface flow
-
surge flow
-
swirling flow
-
swirl flow
-
thermally disordered flow
-
three-dimensional flow
-
throttled flow
-
tidal flow
-
tip-leakage flow
-
total coolant flow
-
total flow
-
total loop flow
-
traffic flow
-
true mass flow
-
turbulent flow
-
two-component flow
-
two-dimensional flow
-
two-phase critical flow
-
two-phase gas-liquid flow
-
unbalanced flow
-
uncontrolled flow
-
undershot orifice flow
-
undimensional heat flow
-
unimpeded flow
-
unit peak flow
-
unsteady-state flow
-
unsteady flow
-
upward flow
-
variable-area flow
-
viscous flow
-
volume flow
-
vortex flow
-
water flow
-
wave flow
-
wavy flow
-
weight flow
-
weir flow
-
well natural flow
-
wind flow
-
wind-induced flow
-
wispy-annular flow
-
working flow
-
yielding flow -
16 modular data center
модульный центр обработки данных (ЦОД)
-
[Интент]Параллельные тексты EN-RU
[ http://dcnt.ru/?p=9299#more-9299]
Data Centers are a hot topic these days. No matter where you look, this once obscure aspect of infrastructure is getting a lot of attention. For years, there have been cost pressures on IT operations and this, when the need for modern capacity is greater than ever, has thrust data centers into the spotlight. Server and rack density continues to rise, placing DC professionals and businesses in tighter and tougher situations while they struggle to manage their IT environments. And now hyper-scale cloud infrastructure is taking traditional technologies to limits never explored before and focusing the imagination of the IT industry on new possibilities.
В настоящее время центры обработки данных являются широко обсуждаемой темой. Куда ни посмотришь, этот некогда малоизвестный аспект инфраструктуры привлекает все больше внимания. Годами ИТ-отделы испытывали нехватку средств и это выдвинуло ЦОДы в центр внимания, в то время, когда необходимость в современных ЦОДах стала как никогда высокой. Плотность серверов и стоек продолжают расти, все больше усложняя ситуацию для специалистов в области охлаждения и организаций в их попытках управлять своими ИТ-средами. И теперь гипермасштабируемая облачная инфраструктура подвергает традиционные технологии невиданным ранее нагрузкам, и заставляет ИТ-индустрию искать новые возможности.
At Microsoft, we have focused a lot of thought and research around how to best operate and maintain our global infrastructure and we want to share those learnings. While obviously there are some aspects that we keep to ourselves, we have shared how we operate facilities daily, our technologies and methodologies, and, most importantly, how we monitor and manage our facilities. Whether it’s speaking at industry events, inviting customers to our “Microsoft data center conferences” held in our data centers, or through other media like blogging and white papers, we believe sharing best practices is paramount and will drive the industry forward. So in that vein, we have some interesting news to share.
В компании MicroSoft уделяют большое внимание изучению наилучших методов эксплуатации и технического обслуживания своей глобальной инфраструктуры и делятся результатами своих исследований. И хотя мы, конечно, не раскрываем некоторые аспекты своих исследований, мы делимся повседневным опытом эксплуатации дата-центров, своими технологиями и методологиями и, что важнее всего, методами контроля и управления своими объектами. Будь то доклады на отраслевых событиях, приглашение клиентов на наши конференции, которые посвящены центрам обработки данных MicroSoft, и проводятся в этих самых дата-центрах, или использование других средств, например, блоги и спецификации, мы уверены, что обмен передовым опытом имеет первостепенное значение и будет продвигать отрасль вперед.
Today we are sharing our Generation 4 Modular Data Center plan. This is our vision and will be the foundation of our cloud data center infrastructure in the next five years. We believe it is one of the most revolutionary changes to happen to data centers in the last 30 years. Joining me, in writing this blog are Daniel Costello, my director of Data Center Research and Engineering and Christian Belady, principal power and cooling architect. I feel their voices will add significant value to driving understanding around the many benefits included in this new design paradigm.
Сейчас мы хотим поделиться своим планом модульного дата-центра четвертого поколения. Это наше видение и оно будет основанием для инфраструктуры наших облачных дата-центров в ближайшие пять лет. Мы считаем, что это одно из самых революционных изменений в дата-центрах за последние 30 лет. Вместе со мной в написании этого блога участвовали Дэниел Костелло, директор по исследованиям и инжинирингу дата-центров, и Кристиан Белади, главный архитектор систем энергоснабжения и охлаждения. Мне кажется, что их авторитет придаст больше веса большому количеству преимуществ, включенных в эту новую парадигму проектирования.
Our “Gen 4” modular data centers will take the flexibility of containerized servers—like those in our Chicago data center—and apply it across the entire facility. So what do we mean by modular? Think of it like “building blocks”, where the data center will be composed of modular units of prefabricated mechanical, electrical, security components, etc., in addition to containerized servers.
Was there a key driver for the Generation 4 Data Center?Наши модульные дата-центры “Gen 4” будут гибкими с контейнерами серверов – как серверы в нашем чикагском дата-центре. И гибкость будет применяться ко всему ЦОД. Итак, что мы подразумеваем под модульностью? Мы думаем о ней как о “строительных блоках”, где дата-центр будет состоять из модульных блоков изготовленных в заводских условиях электрических систем и систем охлаждения, а также систем безопасности и т.п., в дополнение к контейнеризованным серверам.
Был ли ключевой стимул для разработки дата-центра четвертого поколения?
If we were to summarize the promise of our Gen 4 design into a single sentence it would be something like this: “A highly modular, scalable, efficient, just-in-time data center capacity program that can be delivered anywhere in the world very quickly and cheaply, while allowing for continued growth as required.” Sounds too good to be true, doesn’t it? Well, keep in mind that these concepts have been in initial development and prototyping for over a year and are based on cumulative knowledge of previous facility generations and the advances we have made since we began our investments in earnest on this new design.Если бы нам нужно было обобщить достоинства нашего проекта Gen 4 в одном предложении, это выглядело бы следующим образом: “Центр обработки данных с высоким уровнем модульности, расширяемости, и энергетической эффективности, а также возможностью постоянного расширения, в случае необходимости, который можно очень быстро и дешево развертывать в любом месте мира”. Звучит слишком хорошо для того чтобы быть правдой, не так ли? Ну, не забывайте, что эти концепции находились в процессе начальной разработки и создания опытного образца в течение более одного года и основываются на опыте, накопленном в ходе развития предыдущих поколений ЦОД, а также успехах, сделанных нами со времени, когда мы начали вкладывать серьезные средства в этот новый проект.
One of the biggest challenges we’ve had at Microsoft is something Mike likes to call the ‘Goldilock’s Problem’. In a nutshell, the problem can be stated as:
The worst thing we can do in delivering facilities for the business is not have enough capacity online, thus limiting the growth of our products and services.Одну из самых больших проблем, с которыми приходилось сталкиваться Майкрософт, Майк любит называть ‘Проблемой Лютика’. Вкратце, эту проблему можно выразить следующим образом:
Самое худшее, что может быть при строительстве ЦОД для бизнеса, это не располагать достаточными производственными мощностями, и тем самым ограничивать рост наших продуктов и сервисов.The second worst thing we can do in delivering facilities for the business is to have too much capacity online.
А вторым самым худшим моментом в этой сфере может слишком большое количество производственных мощностей.
This has led to a focus on smart, intelligent growth for the business — refining our overall demand picture. It can’t be too hot. It can’t be too cold. It has to be ‘Just Right!’ The capital dollars of investment are too large to make without long term planning. As we struggled to master these interesting challenges, we had to ensure that our technological plan also included solutions for the business and operational challenges we faced as well.
So let’s take a high level look at our Generation 4 designЭто заставило нас сосредоточиваться на интеллектуальном росте для бизнеса — refining our overall demand picture. Это не должно быть слишком горячим. И это не должно быть слишком холодным. Это должно быть ‘как раз, таким как надо!’ Нельзя делать такие большие капиталовложения без долгосрочного планирования. Пока мы старались решить эти интересные проблемы, мы должны были гарантировать, что наш технологический план будет также включать решения для коммерческих и эксплуатационных проблем, с которыми нам также приходилось сталкиваться.
Давайте рассмотрим наш проект дата-центра четвертого поколенияAre you ready for some great visuals? Check out this video at Soapbox. Click here for the Microsoft 4th Gen Video.
It’s a concept video that came out of my Data Center Research and Engineering team, under Daniel Costello, that will give you a view into what we think is the future.
From a configuration, construct-ability and time to market perspective, our primary goals and objectives are to modularize the whole data center. Not just the server side (like the Chicago facility), but the mechanical and electrical space as well. This means using the same kind of parts in pre-manufactured modules, the ability to use containers, skids, or rack-based deployments and the ability to tailor the Redundancy and Reliability requirements to the application at a very specific level.
Посмотрите это видео, перейдите по ссылке для просмотра видео о Microsoft 4th Gen:
Это концептуальное видео, созданное командой отдела Data Center Research and Engineering, возглавляемого Дэниелом Костелло, которое даст вам наше представление о будущем.
С точки зрения конфигурации, строительной технологичности и времени вывода на рынок, нашими главными целями и задачами агрегатирование всего дата-центра. Не только серверную часть, как дата-центр в Чикаго, но также системы охлаждения и электрические системы. Это означает применение деталей одного типа в сборных модулях, возможность использования контейнеров, салазок, или стоечных систем, а также возможность подстраивать требования избыточности и надежности для данного приложения на очень специфичном уровне.Our goals from a cost perspective were simple in concept but tough to deliver. First and foremost, we had to reduce the capital cost per critical Mega Watt by the class of use. Some applications can run with N-level redundancy in the infrastructure, others require a little more infrastructure for support. These different classes of infrastructure requirements meant that optimizing for all cost classes was paramount. At Microsoft, we are not a one trick pony and have many Online products and services (240+) that require different levels of operational support. We understand that and ensured that we addressed it in our design which will allow us to reduce capital costs by 20%-40% or greater depending upon class.
Нашими целями в области затрат были концептуально простыми, но трудно реализуемыми. В первую очередь мы должны были снизить капитальные затраты в пересчете на один мегаватт, в зависимости от класса резервирования. Некоторые приложения могут вполне работать на базе инфраструктуры с резервированием на уровне N, то есть без резервирования, а для работы других приложений требуется больше инфраструктуры. Эти разные классы требований инфраструктуры подразумевали, что оптимизация всех классов затрат имеет преобладающее значение. В Майкрософт мы не ограничиваемся одним решением и располагаем большим количеством интерактивных продуктов и сервисов (240+), которым требуются разные уровни эксплуатационной поддержки. Мы понимаем это, и учитываем это в своем проекте, который позволит нам сокращать капитальные затраты на 20%-40% или более в зависимости от класса.For example, non-critical or geo redundant applications have low hardware reliability requirements on a location basis. As a result, Gen 4 can be configured to provide stripped down, low-cost infrastructure with little or no redundancy and/or temperature control. Let’s say an Online service team decides that due to the dramatically lower cost, they will simply use uncontrolled outside air with temperatures ranging 10-35 C and 20-80% RH. The reality is we are already spec-ing this for all of our servers today and working with server vendors to broaden that range even further as Gen 4 becomes a reality. For this class of infrastructure, we eliminate generators, chillers, UPSs, and possibly lower costs relative to traditional infrastructure.
Например, некритичные или гео-избыточные системы имеют низкие требования к аппаратной надежности на основе местоположения. В результате этого, Gen 4 можно конфигурировать для упрощенной, недорогой инфраструктуры с низким уровнем (или вообще без резервирования) резервирования и / или температурного контроля. Скажем, команда интерактивного сервиса решает, что, в связи с намного меньшими затратами, они будут просто использовать некондиционированный наружный воздух с температурой 10-35°C и влажностью 20-80% RH. В реальности мы уже сегодня предъявляем эти требования к своим серверам и работаем с поставщиками серверов над еще большим расширением диапазона температур, так как наш модуль и подход Gen 4 становится реальностью. Для подобного класса инфраструктуры мы удаляем генераторы, чиллеры, ИБП, и, возможно, будем предлагать более низкие затраты, по сравнению с традиционной инфраструктурой.
Applications that demand higher level of redundancy or temperature control will use configurations of Gen 4 to meet those needs, however, they will also cost more (but still less than traditional data centers). We see this cost difference driving engineering behavioral change in that we predict more applications will drive towards Geo redundancy to lower costs.
Системы, которым требуется более высокий уровень резервирования или температурного контроля, будут использовать конфигурации Gen 4, отвечающие этим требованиям, однако, они будут также стоить больше. Но все равно они будут стоить меньше, чем традиционные дата-центры. Мы предвидим, что эти различия в затратах будут вызывать изменения в методах инжиниринга, и по нашим прогнозам, это будет выражаться в переходе все большего числа систем на гео-избыточность и меньшие затраты.
Another cool thing about Gen 4 is that it allows us to deploy capacity when our demand dictates it. Once finalized, we will no longer need to make large upfront investments. Imagine driving capital costs more closely in-line with actual demand, thus greatly reducing time-to-market and adding the capacity Online inherent in the design. Also reduced is the amount of construction labor required to put these “building blocks” together. Since the entire platform requires pre-manufacture of its core components, on-site construction costs are lowered. This allows us to maximize our return on invested capital.
Еще одно достоинство Gen 4 состоит в том, что он позволяет нам разворачивать дополнительные мощности, когда нам это необходимо. Как только мы закончим проект, нам больше не нужно будет делать большие начальные капиталовложения. Представьте себе возможность более точного согласования капитальных затрат с реальными требованиями, и тем самым значительного снижения времени вывода на рынок и интерактивного добавления мощностей, предусматриваемого проектом. Также снижен объем строительных работ, требуемых для сборки этих “строительных блоков”. Поскольку вся платформа требует предварительного изготовления ее базовых компонентов, затраты на сборку также снижены. Это позволит нам увеличить до максимума окупаемость своих капиталовложений.
Мы все подвергаем сомнениюIn our design process, we questioned everything. You may notice there is no roof and some might be uncomfortable with this. We explored the need of one and throughout our research we got some surprising (positive) results that showed one wasn’t needed.
В своем процессе проектирования мы все подвергаем сомнению. Вы, наверное, обратили внимание на отсутствие крыши, и некоторым специалистам это могло не понравиться. Мы изучили необходимость в крыше и в ходе своих исследований получили удивительные результаты, которые показали, что крыша не нужна.
Серийное производство дата центров
In short, we are striving to bring Henry Ford’s Model T factory to the data center. http://en.wikipedia.org/wiki/Henry_Ford#Model_T. Gen 4 will move data centers from a custom design and build model to a commoditized manufacturing approach. We intend to have our components built in factories and then assemble them in one location (the data center site) very quickly. Think about how a computer, car or plane is built today. Components are manufactured by different companies all over the world to a predefined spec and then integrated in one location based on demands and feature requirements. And just like Henry Ford’s assembly line drove the cost of building and the time-to-market down dramatically for the automobile industry, we expect Gen 4 to do the same for data centers. Everything will be pre-manufactured and assembled on the pad.Мы хотим применить модель автомобильной фабрики Генри Форда к дата-центру. Проект Gen 4 будет способствовать переходу от модели специализированного проектирования и строительства к товарно-производственному, серийному подходу. Мы намерены изготавливать свои компоненты на заводах, а затем очень быстро собирать их в одном месте, в месте строительства дата-центра. Подумайте о том, как сегодня изготавливается компьютер, автомобиль или самолет. Компоненты изготавливаются по заранее определенным спецификациям разными компаниями во всем мире, затем собираются в одном месте на основе спроса и требуемых характеристик. И точно так же как сборочный конвейер Генри Форда привел к значительному уменьшению затрат на производство и времени вывода на рынок в автомобильной промышленности, мы надеемся, что Gen 4 сделает то же самое для дата-центров. Все будет предварительно изготавливаться и собираться на месте.
Невероятно энергоэффективный ЦОД
And did we mention that this platform will be, overall, incredibly energy efficient? From a total energy perspective not only will we have remarkable PUE values, but the total cost of energy going into the facility will be greatly reduced as well. How much energy goes into making concrete? Will we need as much of it? How much energy goes into the fuel of the construction vehicles? This will also be greatly reduced! A key driver is our goal to achieve an average PUE at or below 1.125 by 2012 across our data centers. More than that, we are on a mission to reduce the overall amount of copper and water used in these facilities. We believe these will be the next areas of industry attention when and if the energy problem is solved. So we are asking today…“how can we build a data center with less building”?А мы упоминали, что эта платформа будет, в общем, невероятно энергоэффективной? С точки зрения общей энергии, мы получим не только поразительные значения PUE, но общая стоимость энергии, затраченной на объект будет также значительно снижена. Сколько энергии идет на производство бетона? Нам нужно будет столько энергии? Сколько энергии идет на питание инженерных строительных машин? Это тоже будет значительно снижено! Главным стимулом является достижение среднего PUE не больше 1.125 для всех наших дата-центров к 2012 году. Более того, у нас есть задача сокращения общего количества меди и воды в дата-центрах. Мы думаем, что эти задачи станут следующей заботой отрасли после того как будет решена энергетическая проблема. Итак, сегодня мы спрашиваем себя…“как можно построить дата-центр с меньшим объемом строительных работ”?
Строительство дата центров без чиллеровWe have talked openly and publicly about building chiller-less data centers and running our facilities using aggressive outside economization. Our sincerest hope is that Gen 4 will completely eliminate the use of water. Today’s data centers use massive amounts of water and we see water as the next scarce resource and have decided to take a proactive stance on making water conservation part of our plan.
Мы открыто и публично говорили о строительстве дата-центров без чиллеров и активном использовании в наших центрах обработки данных технологий свободного охлаждения или фрикулинга. Мы искренне надеемся, что Gen 4 позволит полностью отказаться от использования воды. Современные дата-центры расходуют большие объемы воды и так как мы считаем воду следующим редким ресурсом, мы решили принять упреждающие меры и включить экономию воды в свой план.
By sharing this with the industry, we believe everyone can benefit from our methodology. While this concept and approach may be intimidating (or downright frightening) to some in the industry, disclosure ultimately is better for all of us.
Делясь этим опытом с отраслью, мы считаем, что каждый сможет извлечь выгоду из нашей методологией. Хотя эта концепция и подход могут показаться пугающими (или откровенно страшными) для некоторых отраслевых специалистов, раскрывая свои планы мы, в конечном счете, делаем лучше для всех нас.
Gen 4 design (even more than just containers), could reduce the ‘religious’ debates in our industry. With the central spine infrastructure in place, containers or pre-manufactured server halls can be either AC or DC, air-side economized or water-side economized, or not economized at all (though the sanity of that might be questioned). Gen 4 will allow us to decommission, repair and upgrade quickly because everything is modular. No longer will we be governed by the initial decisions made when constructing the facility. We will have almost unlimited use and re-use of the facility and site. We will also be able to use power in an ultra-fluid fashion moving load from critical to non-critical as use and capacity requirements dictate.
Проект Gen 4 позволит уменьшить ‘религиозные’ споры в нашей отрасли. Располагая базовой инфраструктурой, контейнеры или сборные серверные могут оборудоваться системами переменного или постоянного тока, воздушными или водяными экономайзерами, или вообще не использовать экономайзеры. Хотя можно подвергать сомнению разумность такого решения. Gen 4 позволит нам быстро выполнять работы по выводу из эксплуатации, ремонту и модернизации, поскольку все будет модульным. Мы больше не будем руководствоваться начальными решениями, принятыми во время строительства дата-центра. Мы сможем использовать этот дата-центр и инфраструктуру в течение почти неограниченного периода времени. Мы также сможем применять сверхгибкие методы использования электрической энергии, переводя оборудование в режимы критической или некритической нагрузки в соответствии с требуемой мощностью.
Gen 4 – это стандартная платформаFinally, we believe this is a big game changer. Gen 4 will provide a standard platform that our industry can innovate around. For example, all modules in our Gen 4 will have common interfaces clearly defined by our specs and any vendor that meets these specifications will be able to plug into our infrastructure. Whether you are a computer vendor, UPS vendor, generator vendor, etc., you will be able to plug and play into our infrastructure. This means we can also source anyone, anywhere on the globe to minimize costs and maximize performance. We want to help motivate the industry to further innovate—with innovations from which everyone can reap the benefits.
Наконец, мы уверены, что это будет фактором, который значительно изменит ситуацию. Gen 4 будет представлять собой стандартную платформу, которую отрасль сможет обновлять. Например, все модули в нашем Gen 4 будут иметь общепринятые интерфейсы, четко определяемые нашими спецификациями, и оборудование любого поставщика, которое отвечает этим спецификациям можно будет включать в нашу инфраструктуру. Независимо от того производите вы компьютеры, ИБП, генераторы и т.п., вы сможете включать свое оборудование нашу инфраструктуру. Это означает, что мы также сможем обеспечивать всех, в любом месте земного шара, тем самым сводя до минимума затраты и максимальной увеличивая производительность. Мы хотим создать в отрасли мотивацию для дальнейших инноваций – инноваций, от которых каждый сможет получать выгоду.
Главные характеристики дата-центров четвертого поколения Gen4To summarize, the key characteristics of our Generation 4 data centers are:
Scalable
Plug-and-play spine infrastructure
Factory pre-assembled: Pre-Assembled Containers (PACs) & Pre-Manufactured Buildings (PMBs)
Rapid deployment
De-mountable
Reduce TTM
Reduced construction
Sustainable measuresНиже приведены главные характеристики дата-центров четвертого поколения Gen 4:
Расширяемость;
Готовая к использованию базовая инфраструктура;
Изготовление в заводских условиях: сборные контейнеры (PAC) и сборные здания (PMB);
Быстрота развертывания;
Возможность демонтажа;
Снижение времени вывода на рынок (TTM);
Сокращение сроков строительства;
Экологичность;Map applications to DC Class
We hope you join us on this incredible journey of change and innovation!
Long hours of research and engineering time are invested into this process. There are still some long days and nights ahead, but the vision is clear. Rest assured however, that we as refine Generation 4, the team will soon be looking to Generation 5 (even if it is a bit farther out). There is always room to get better.
Использование систем электропитания постоянного тока.
Мы надеемся, что вы присоединитесь к нам в этом невероятном путешествии по миру изменений и инноваций!
На этот проект уже потрачены долгие часы исследований и проектирования. И еще предстоит потратить много дней и ночей, но мы имеем четкое представление о конечной цели. Однако будьте уверены, что как только мы доведем до конца проект модульного дата-центра четвертого поколения, мы вскоре начнем думать о проекте дата-центра пятого поколения. Всегда есть возможность для улучшений.So if you happen to come across Goldilocks in the forest, and you are curious as to why she is smiling you will know that she feels very good about getting very close to ‘JUST RIGHT’.
Generations of Evolution – some background on our data center designsТак что, если вы встретите в лесу девочку по имени Лютик, и вам станет любопытно, почему она улыбается, вы будете знать, что она очень довольна тем, что очень близко подошла к ‘ОПИМАЛЬНОМУ РЕШЕНИЮ’.
Поколения эволюции – история развития наших дата-центровWe thought you might be interested in understanding what happened in the first three generations of our data center designs. When Ray Ozzie wrote his Software plus Services memo it posed a very interesting challenge to us. The winds of change were at ‘tornado’ proportions. That “plus Services” tag had some significant (and unstated) challenges inherent to it. The first was that Microsoft was going to evolve even further into an operations company. While we had been running large scale Internet services since 1995, this development lead us to an entirely new level. Additionally, these “services” would span across both Internet and Enterprise businesses. To those of you who have to operate “stuff”, you know that these are two very different worlds in operational models and challenges. It also meant that, to achieve the same level of reliability and performance required our infrastructure was going to have to scale globally and in a significant way.
Мы подумали, что может быть вам будет интересно узнать историю первых трех поколений наших центров обработки данных. Когда Рэй Оззи написал свою памятную записку Software plus Services, он поставил перед нами очень интересную задачу. Ветра перемен двигались с ураганной скоростью. Это окончание “plus Services” скрывало в себе какие-то значительные и неопределенные задачи. Первая заключалась в том, что Майкрософт собиралась в еще большей степени стать операционной компанией. Несмотря на то, что мы управляли большими интернет-сервисами, начиная с 1995 г., эта разработка подняла нас на абсолютно новый уровень. Кроме того, эти “сервисы” охватывали интернет-компании и корпорации. Тем, кому приходится всем этим управлять, известно, что есть два очень разных мира в области операционных моделей и задач. Это также означало, что для достижения такого же уровня надежности и производительности требовалось, чтобы наша инфраструктура располагала значительными возможностями расширения в глобальных масштабах.
It was that intense atmosphere of change that we first started re-evaluating data center technology and processes in general and our ideas began to reach farther than what was accepted by the industry at large. This was the era of Generation 1. As we look at where most of the world’s data centers are today (and where our facilities were), it represented all the known learning and design requirements that had been in place since IBM built the first purpose-built computer room. These facilities focused more around uptime, reliability and redundancy. Big infrastructure was held accountable to solve all potential environmental shortfalls. This is where the majority of infrastructure in the industry still is today.
Именно в этой атмосфере серьезных изменений мы впервые начали переоценку ЦОД-технологий и технологий вообще, и наши идеи начали выходить за пределы общепринятых в отрасли представлений. Это была эпоха ЦОД первого поколения. Когда мы узнали, где сегодня располагается большинство мировых дата-центров и где находятся наши предприятия, это представляло весь опыт и навыки проектирования, накопленные со времени, когда IBM построила первую серверную. В этих ЦОД больше внимания уделялось бесперебойной работе, надежности и резервированию. Большая инфраструктура была призвана решать все потенциальные экологические проблемы. Сегодня большая часть инфраструктуры все еще находится на этом этапе своего развития.
We soon realized that traditional data centers were quickly becoming outdated. They were not keeping up with the demands of what was happening technologically and environmentally. That’s when we kicked off our Generation 2 design. Gen 2 facilities started taking into account sustainability, energy efficiency, and really looking at the total cost of energy and operations.
Очень быстро мы поняли, что стандартные дата-центры очень быстро становятся устаревшими. Они не поспевали за темпами изменений технологических и экологических требований. Именно тогда мы стали разрабатывать ЦОД второго поколения. В этих дата-центрах Gen 2 стали принимать во внимание такие факторы как устойчивое развитие, энергетическая эффективность, а также общие энергетические и эксплуатационные.
No longer did we view data centers just for the upfront capital costs, but we took a hard look at the facility over the course of its life. Our Quincy, Washington and San Antonio, Texas facilities are examples of our Gen 2 data centers where we explored and implemented new ways to lessen the impact on the environment. These facilities are considered two leading industry examples, based on their energy efficiency and ability to run and operate at new levels of scale and performance by leveraging clean hydro power (Quincy) and recycled waste water (San Antonio) to cool the facility during peak cooling months.
Мы больше не рассматривали дата-центры только с точки зрения начальных капитальных затрат, а внимательно следили за работой ЦОД на протяжении его срока службы. Наши объекты в Куинси, Вашингтоне, и Сан-Антонио, Техас, являются образцами наших ЦОД второго поколения, в которых мы изучали и применяли на практике новые способы снижения воздействия на окружающую среду. Эти объекты считаются двумя ведущими отраслевыми примерами, исходя из их энергетической эффективности и способности работать на новых уровнях производительности, основанных на использовании чистой энергии воды (Куинси) и рециклирования отработанной воды (Сан-Антонио) для охлаждения объекта в самых жарких месяцах.
As we were delivering our Gen 2 facilities into steel and concrete, our Generation 3 facilities were rapidly driving the evolution of the program. The key concepts for our Gen 3 design are increased modularity and greater concentration around energy efficiency and scale. The Gen 3 facility will be best represented by the Chicago, Illinois facility currently under construction. This facility will seem very foreign compared to the traditional data center concepts most of the industry is comfortable with. In fact, if you ever sit around in our container hanger in Chicago it will look incredibly different from a traditional raised-floor data center. We anticipate this modularization will drive huge efficiencies in terms of cost and operations for our business. We will also introduce significant changes in the environmental systems used to run our facilities. These concepts and processes (where applicable) will help us gain even greater efficiencies in our existing footprint, allowing us to further maximize infrastructure investments.
Так как наши ЦОД второго поколения строились из стали и бетона, наши центры обработки данных третьего поколения начали их быстро вытеснять. Главными концептуальными особенностями ЦОД третьего поколения Gen 3 являются повышенная модульность и большее внимание к энергетической эффективности и масштабированию. Дата-центры третьего поколения лучше всего представлены объектом, который в настоящее время строится в Чикаго, Иллинойс. Этот ЦОД будет выглядеть очень необычно, по сравнению с общепринятыми в отрасли представлениями о дата-центре. Действительно, если вам когда-либо удастся побывать в нашем контейнерном ангаре в Чикаго, он покажется вам совершенно непохожим на обычный дата-центр с фальшполом. Мы предполагаем, что этот модульный подход будет способствовать значительному повышению эффективности нашего бизнеса в отношении затрат и операций. Мы также внесем существенные изменения в климатические системы, используемые в наших ЦОД. Эти концепции и технологии, если применимо, позволят нам добиться еще большей эффективности наших существующих дата-центров, и тем самым еще больше увеличивать капиталовложения в инфраструктуру.
This is definitely a journey, not a destination industry. In fact, our Generation 4 design has been under heavy engineering for viability and cost for over a year. While the demand of our commercial growth required us to make investments as we grew, we treated each step in the learning as a process for further innovation in data centers. The design for our future Gen 4 facilities enabled us to make visionary advances that addressed the challenges of building, running, and operating facilities all in one concerted effort.
Это определенно путешествие, а не конечный пункт назначения. На самом деле, наш проект ЦОД четвертого поколения подвергался серьезным испытаниям на жизнеспособность и затраты на протяжении целого года. Хотя необходимость в коммерческом росте требовала от нас постоянных капиталовложений, мы рассматривали каждый этап своего развития как шаг к будущим инновациям в области дата-центров. Проект наших будущих ЦОД четвертого поколения Gen 4 позволил нам делать фантастические предположения, которые касались задач строительства, управления и эксплуатации объектов как единого упорядоченного процесса.
Тематики
Синонимы
EN
Англо-русский словарь нормативно-технической терминологии > modular data center
-
17 current
1) (электрический) ток || токовый2) поток; течение || текущий; протекающий3) скорость потока; скорость течения4) течение; ход событий || текущий; относящийся к рассматриваемому моменту времени; современный6) общая тенденция; курс || общепринятый; общераспространённый•- acoustoelectric current
- action current
- active current
- alternating current
- anode current
- antenna current
- arc current
- armature current
- avalanche current
- average current
- back current
- balanced currents
- band-to-band current
- base current
- beam current
- bias current
- biasing current
- bidirectional current
- biphase current
- bleeder current
- blowing current
- branch current
- breakaway current
- breakaway starting current
- breakdown current
- breaking current
- breakover current
- bulk current
- carrier current
- catcher current
- cathode current
- cathode covering current
- cathode-ray current
- channel current
- charging current
- collector current
- collector cutoff current
- collector-junction current
- collector leakage current
- collector-saturation current
- complex current
- complex sinusoidal current
- conduction current
- conjugate complex current
- conjugate complex sinusoidal current
- constant current
- continuous current
- control current
- convection current
- conventional fusing current
- conventional nonfusing current
- critical current
- critical controlling current
- critical grid current
- crystal current
- cutoff current
- cyclic current
- damped current
- dark current
- decaying current
- demarcation current
- diacritical current
- dielectric current
- diffusion current
- digit current
- direct current
- discharge current
- displacement current
- double-injection current
- drain current
- drift current
- drop-away current
- drop-out current
- earth current
- echo current
- eddy currents
- edge leakage current
- effective current
- electric current
- electric induction current
- electrode current
- electrode dark current
- electrode inverse current
- electron current
- emission current
- emitter current
- equivalent input offset current
- equivalent noise current
- erasing current
- excess current
- excitation current
- exciting current
- exponential excess current
- external current
- extra current
- extraction current
- extraneous current
- faradic current
- fault current
- fault electrode current
- feedback current
- field-free emission current
- filament starting current
- filament surge current
- firing current
- flash current
- flection-point emission current
- fluctuating current
- focus current
- focusing current
- follow current
- forward current
- forward-bias current
- Foucault currents
- Frenkel-Poole current
- full-select current
- fusing current
- galvanic current
- gap current
- gas current
- gas ionization current
- gate current
- gate-body leakage current
- gate holding current
- gate nontrigger current
- gate trigger current
- gate turn-off current
- generation-recombination current
- grid current
- ground current
- gun current
- half-select current
- Hall current
- harmonic current
- heater current
- heater-cathode current
- heater-cathode insulation current
- heater starting current
- heater surge current
- heavy current
- high-frequency current
- high-tension current
- high-voltage direct current
- hold current
- holding current
- hole current
- hot-electron current
- hump current
- idle current
- idling current
- image current
- impurity diffusion current
- incident current
- induced current
- inflection-point emission current
- initial symmetrical short-circuit current
- initial-velocity current
- injection current
- input offset current
- interbase current
- intermittent current
- inverse current
- ion current
- ionic current
- ionization current
- irradiation saturation current
- Josephson tunnel current
- lagging current
- latching current
- leading current
- leakage current
- leakage tube current
- Leduc current
- light current
- limiting slider current
- load current
- local current
- locked-rotor current
- longitudinal current
- loop current
- magnetization current
- magnetizing current
- majority current
- majority-carrier current
- make-and-break current
- making current
- marker current
- marking current
- mesh current
- minority current
- minority-carrier current
- Morton wave current
- nerve-action current
- net current
- noise current
- no-load current
- offset current
- off-state current
- one-carrier current
- one-particle current
- open-circuit current
- operating current
- oscillating current
- oscillatory current
- over current
- paired-electron current
- particle current
- peak inverse anode current
- peak plate current
- peak-point current
- peak-switching current
- peak-withstand current
- pedestal current
- periodic current
- persistent current
- phasor current
- photoelectric current
- photon-induced current
- pick-up current
- piezoelectric current
- pinch current
- pinch-off current
- plate current
- poloidal current
- post-arc current
- prebreakdown current
- preconduction current
- preionization current
- preoscillation current
- primary current
- probability current
- probe current
- prospective current
- pull-in current
- pulsating current
- push-pull currents
- push-push currents
- pyroelectric current
- quiescent current
- radiation-induced current
- radiation-induced thermally activated current
- rated current
- rated ac discharge current
- rated coil current
- rated contact current
- rated follow current
- reactive current
- read current
- read-out current
- recombination-generation current
- recording audio-frequency current
- recovery current
- rectified current
- reflected current
- regeneration current
- release current
- residual current
- residual stored current
- resistor-substrate leakage current
- return current
- reverse current
- reverse-bias current
- reverse blocking current
- reverse leakage current
- reverse recovery current
- reverse saturation current
- reversible absorption current
- RF current
- ringing current
- ripple current
- saturation current
- sawtooth current
- SCL current
- secondary current
- selection current
- short-circuit current
- short-circuit current per unit wavelength
- short-time withstand current
- signal output current
- simple harmonic current
- single-electron current
- single-injection current
- sinusoidal current
- skinned current
- sneak current
- source current
- space current
- space-charge-limited current
- spacing current
- spin-polarized current
- split-phase current
- sputtering current
- standing current
- starter transfer current
- starting current
- steady current
- steady short-circuit current
- steady-state current
- stray current
- subthreshold current
- surface current
- surge current
- surge electrode current
- sustaining current
- sweeping-out current
- switching current
- synaptic current
- take-off current
- target current
- telephone current
- telephone carrier current
- telluric current
- thermal current
- thermal-convection current
- thermally activated current
- thermionic current
- three-phase current
- threshold current
- toroidal current
- total current
- transfer current
- transient current
- transient-decay current
- tree-branch current
- tunnel current
- tunneling current
- turn-on base current
- turnover current
- two-carrier current
- undulating current
- undulatory current
- unidirectional current
- unit-step current
- vacancy current
- valley current
- valley-point current
- vector current
- video current
- video record current
- voltage saturation current
- voltaic current
- write current
- Zener current
- zero-field emission current
- zero-voltage current -
18 current
1) (электрический) ток || токовый2) поток; течение || текущий; протекающий3) скорость потока; скорость течения4) течение; ход событий || текущий; относящийся к рассматриваемому моменту времени; современный5) вчт. рабочий (напр. о файле); текущий (напр. о записи)6) общая тенденция; курс || общепринятый; общераспространённый•- acoustoelectric current
- action current
- active current
- alternating current
- anode current
- antenna current
- arc current
- armature current
- avalanche current
- average current
- back current
- balanced currents
- band-to-band current
- base current
- beam current
- bias current
- biasing current
- bidirectional current
- biphase current
- bleeder current
- blowing current
- branch current
- breakaway current
- breakaway starting current
- breakdown current
- breaking current
- breakover current
- bulk current
- carrier current
- catcher current
- cathode covering current
- cathode current
- cathode-ray current
- channel current
- charging current
- collector current
- collector cutoff current
- collector leakage current
- collector-junction current
- collector-saturation current
- complex current
- complex sinusoidal current
- conduction current
- conjugate complex current
- conjugate complex sinusoidal current
- constant current
- continuous current
- control current
- convection current
- conventional fusing current
- conventional nonfusing current
- critical controlling current
- critical current
- critical grid current
- crystal current
- cutoff current
- cyclic current
- damped current
- dark current
- decaying current
- demarcation current
- diacritical current
- dielectric current
- diffusion current
- digit current
- direct current
- discharge current
- displacement current
- double-injection current
- drain current
- drift current
- drop-away current
- drop-out current
- earth current
- echo current
- eddy currents
- edge leakage current
- effective current
- electric current
- electric induction current
- electrode current
- electrode dark current
- electrode inverse current
- electron current
- emission current
- emitter current
- equivalent input offset current
- equivalent noise current
- erasing current
- excess current
- excitation current
- exciting current
- exponential excess current
- external current
- extra current
- extraction current
- extraneous current
- faradic current
- fault current
- fault electrode current
- feedback current
- field-free emission current
- filament starting current
- filament surge current
- firing current
- flash current
- flection-point emission current
- fluctuating current
- focus current
- focusing current
- follow current
- forward current
- forward-bias current
- Foucault currents
- Frenkel-Poole current
- full-select current
- fusing current
- galvanic current
- gap current
- gas current
- gas ionization current
- gate current
- gate holding current
- gate nontrigger current
- gate trigger current
- gate turn-off current
- gate-body leakage current
- generation-recombination current
- grid current
- ground current
- gun current
- half-select current
- Hall current
- harmonic current
- heater current
- heater starting current
- heater surge current
- heater-cathode current
- heater-cathode insulation current
- heavy current
- high-frequency current
- high-tension current
- high-voltage direct current
- hold current
- holding current
- hole current
- hot-electron current
- hump current
- idle current
- idling current
- image current
- impurity diffusion current
- incident current
- induced current
- inflection-point emission current
- initial symmetrical short-circuit current
- initial-velocity current
- injection current
- input offset current
- interbase current
- intermittent current
- inverse current
- ion current
- ionic current
- ionization current
- irradiation saturation current
- Josephson tunnel current
- lagging current
- latching current
- leading current
- leakage current
- leakage tube current
- Leduc current
- light current
- limiting slider current
- load current
- local current
- locked-rotor current
- longitudinal current
- loop current
- magnetization current
- magnetizing current
- majority current
- majority-carrier current
- make-and-break current
- making current
- marker current
- marking current
- mesh current
- minority current
- minority-carrier current
- Morton wave current
- nerve-action current
- net current
- noise current
- no-load current
- offset current
- off-state current
- one-carrier current
- one-particle current
- open-circuit current
- operating current
- oscillating current
- oscillatory current
- over current
- paired-electron current
- particle current
- peak inverse anode current
- peak plate current
- peak-point current
- peak-switching current
- peak-withstand current
- pedestal current
- periodic current
- persistent current
- phasor current
- photoelectric current
- photon-induced current
- pick-up current
- piezoelectric current
- pinch current
- pinch-off current
- plate current
- poloidal current
- post-arc current
- prebreakdown current
- preconduction current
- preionization current
- preoscillation current
- primary current
- probability current
- probe current
- prospective current
- pull-in current
- pulsating current
- push-pull currents
- push-push currents
- pyroelectric current
- quiescent current
- radiation-induced current
- radiation-induced thermally activated current
- rated ac discharge current
- rated coil current
- rated contact current
- rated current
- rated follow current
- reactive current
- read current
- read-out current
- recombination-generation current
- recording audio-frequency current
- recovery current
- rectified current
- reflected current
- regeneration current
- release current
- residual current
- residual stored current
- resistor-substrate leakage current
- return current
- reverse blocking current
- reverse current
- reverse leakage current
- reverse recovery current
- reverse saturation current
- reverse-bias current
- reversible absorption current
- RF current
- ringing current
- ripple current
- saturation current
- sawtooth current
- SCL current
- secondary current
- selection current
- short-circuit current per unit wavelength
- short-circuit current
- short-time withstand current
- signal output current
- simple harmonic current
- single-electron current
- single-injection current
- sinusoidal current
- skinned current
- sneak current
- source current
- space current
- space-charge-limited current
- spacing current
- spin-polarized current
- split-phase current
- sputtering current
- standing current
- starter transfer current
- starting current
- steady current
- steady short-circuit current
- steady-state current
- stray current
- subthreshold current
- surface current
- surge current
- surge electrode current
- sustaining current
- sweeping-out current
- switching current
- synaptic current
- take-off current
- target current
- telephone carrier current
- telephone current
- telluric current
- thermal current
- thermal-convection current
- thermally activated current
- thermionic current
- three-phase current
- threshold current
- toroidal current
- total current
- transfer current
- transient current
- transient-decay current
- tree-branch current
- tunnel current
- tunneling current
- turn-on base current
- turnover current
- two-carrier current
- undulating current
- undulatory current
- unidirectional current
- unit-step current
- vacancy current
- valley current
- valley-point current
- vector current
- video current
- video record current
- voltage saturation current
- voltaic current
- write current
- Zener current
- zero-field emission current
- zero-voltage currentThe New English-Russian Dictionary of Radio-electronics > current
-
19 area
1) площадь; пространство3) поверхность4) (производственный) участок; помещение; площадка5) рабочая ячейка ( склада)•equal in area — равновеликий;area of base — площадь основания, площадь подошвы фундаментаarea of bearing — 1. площадь опоры 2. строит. площадка опиранияarea of contact — площадь поверхности контактаarea of diagram — площадь эпюры; площадь графикаarea of fracture — 1. поверхность излома 2. площадь поперечного сечения в месте разрушенияarea of occurrence — возд. район происшествияarea of water section — гидр. площадь живого сечения потокаarea of well influence — зона влияния колодца или скважины-
absorption area
-
active area
-
actual contact area
-
actuating area
-
actuation probability area
-
addressable area
-
adjustment control area
-
advisory area
-
air intake hazard area
-
aircraft parking area
-
airflow separation area
-
airport construction area
-
airport prohibited area
-
airport service area
-
air-route area
-
alighting area
-
alloy storage area
-
annulus area
-
antenna effective area
-
antenna area
-
antinode area
-
aperture area
-
approach area
-
ash-disposal area
-
auditory area
-
backwater area
-
bare area
-
base area
-
bearing surface area
-
binding area
-
blade area
-
blade-exit area
-
blind area
-
blind drainage area
-
boarding area
-
bolted area
-
bonding area
-
bond area
-
bore area
-
bubble-melt surface area
-
buffer area
-
building area
-
built-up area
-
burning area
-
catalyst surface area
-
catchment area
-
caved area
-
central equipment area
-
centralized telecine area
-
centralized traffic area
-
centralized video tape area
-
charge-makeup area
-
charging area
-
chip area
-
choke-tube area
-
circling approach area
-
clean processing area
-
clearance area
-
climb-out area
-
clinch area
-
coal area
-
coherence area
-
cold area
-
commanded area
-
common area
-
compression area
-
concrete area
-
cone effect area
-
congested area
-
connector area
-
conservation area
-
constant area
-
contact area
-
contact spot area
-
contaminated area
-
contamination control area
-
contiguous area
-
contour area of contact
-
control area
-
controlled access area
-
cooling area
-
corrosion area
-
coverage area
-
crimp area
-
critical area
-
cross-sectional area
-
cross-section area
-
cutting area
-
cylinder annular area
-
dangerous area
-
data-rich area
-
data-sparse area
-
data-void area
-
decontamination area
-
demixing area
-
design wing area
-
developed area
-
developed blade area
-
development area
-
die attach area
-
diked area
-
direct transit area
-
discharge area
-
display area
-
disposal area
-
dot area
-
downstream area
-
drainage area
-
drainless area
-
dry area
-
dynamic area
-
echoing area
-
echo area
-
effective area
-
effective braking area
-
effective cross-sectional area
-
effective cross-section area
-
effective screening area
-
effects area
-
electrical contact area
-
electroded area
-
elemental area
-
enclosed working area
-
end safety area
-
engineering area
-
environmentally fragile area
-
exchange area
-
exclusion area
-
exhaust area
-
expanded blade area
-
expanded area
-
exposure area
-
face area
-
fan blast area
-
felling area
-
fenced-off area
-
fetch area
-
fill area
-
film-editing area
-
filter effective area
-
filter open area
-
filtering area
-
finished-products storage area
-
fixed area
-
flame area
-
flooded area
-
flood-free area
-
flooding area
-
floor area
-
flow area
-
focus area
-
forbidden area
-
free-surface area
-
fringe area
-
functional area
-
furnace area
-
fusing area
-
fusion area
-
gases shear area
-
gasket surface area
-
gassy area
-
gathering area
-
gob area
-
graticule area
-
gray-scale picture area
-
gross cross-sectional area
-
gross cross-section area
-
gross irrigable area
-
ground contact area
-
gutter area
-
hard-core area
-
hard-to-reach area
-
hearth area
-
heat dissipation area
-
heat-affected area
-
heating area
-
heat-transfer area
-
high-activity area
-
high-beat area
-
high-radiation area
-
holding area
-
hot area
-
housing area
-
illuminated area
-
image area
-
impact area
-
impression area
-
inactive area
-
ingot-stripping area
-
input area
-
instantaneous area of flame front
-
instruction area
-
intended landing area
-
interfacial area
-
interference area
-
interlocking area
-
inundated area
-
junction area
-
knuckle area
-
land area
-
landing area
-
lateral area
-
lift irrigation area
-
lift-off area
-
link overlapped area
-
living area
-
living floor area
-
load-and-unload area
-
load-carrying area
-
loading area
-
loadout area
-
localized areas of wear
-
low-radiation area
-
makeup area
-
maneuvering area
-
man-impacted area
-
manned area
-
manual setting-up area
-
melting area
-
mesa area
-
metropolitan area
-
mining area
-
mirror area
-
mold conditioning area
-
mold opening area
-
moment area
-
movement area
-
mush area
-
natural area
-
net cross-sectional area
-
net cross-section area
-
neutron migration area
-
nominal contact area
-
noncontact area
-
nonimage area
-
nonmoving area
-
nonoccupied area
-
nonprinting area
-
nonstorage area
-
nonutilizable area
-
normally occupied area
-
nose area
-
nuclear area
-
numbering area
-
obstructed landing area
-
open area
-
open flow area
-
outgassed area
-
output area
-
overrun safety area
-
pallet area
-
patch area
-
pattern area
-
payable area
-
percent shear area
-
personnel and utility area
-
phosphor area
-
photolithographic area
-
picture area
-
poor-reception area
-
port area
-
presentation area
-
pressing area
-
prewarming area
-
primary area
-
primary service area
-
printing area
-
production area
-
production control area
-
programmed operating area
-
prohibited area
-
projectedblade area
-
projected area
-
propeller disk area
-
protected area
-
quality-control area
-
quality area
-
quench area
-
quiet area
-
radar area
-
radiation-control area
-
real area of contact
-
recording area
-
record area
-
refining area
-
regeneration area
-
reinforcing steel area
-
rerecording area
-
reservoir surface area
-
reservoir area
-
residential area
-
resident area
-
residential floor area
-
restricted area
-
retarder area
-
rig deck area
-
risk area
-
robot area
-
roof contact area
-
rubbing path area
-
rudder area
-
run-up area
-
rural area
-
safe operating area
-
safety area
-
sail area
-
save area
-
scanned area
-
scrap-consuming area
-
scrap-disposal area
-
scrap-grading area
-
scratch area
-
screen area
-
sealing area
-
seal area
-
search area
-
secondary area
-
sectional area
-
section area
-
seeking area
-
segregated area
-
service area
-
serviceable area
-
setting-up area
-
shaded area
-
shadow area
-
shareable area
-
shoe pad transition area
-
shooting area
-
sintering area
-
site area
-
skip area
-
slag-line area
-
slot area
-
slowing-down area of neutron
-
snow-covered area
-
solid area
-
sound area
-
sound-track area
-
special work permit area
-
specific floor area
-
specific surface area
-
spliced area
-
spoil area
-
stack area
-
stockline area
-
stool conditioning area
-
storage area
-
stripped area
-
subsidence area
-
superheated area
-
surface area
-
switching area
-
takeoff area
-
takeoff flight path area
-
tape area
-
taphole area
-
target area
-
technical-equipment area
-
technical area
-
telecine area
-
tension area
-
terminal area
-
terminal control area
-
test area
-
throat area
-
tongs area of pipe
-
tool service area
-
tool-presetting area
-
total area
-
total irrigation area
-
total tuyere area
-
transient area
-
turnaround area
-
tuyere area
-
type area
-
unattacked area
-
undershoot area
-
ungaged area
-
uniform area
-
unobstructed landing area
-
upstream area
-
urban area
-
usable area
-
user area
-
valve fillet area
-
valve seating face area
-
video tape recording area
-
video tape area
-
viewing area
-
vision control area
-
vulnerable area
-
waste area
-
waste-metal area
-
waste-storage area
-
water catchment area
-
waterplane area
-
water-surface area
-
wear track area
-
weld metal area
-
well drainage area
-
wellhead area
-
wetted area
-
wildlife area
-
window area
-
worked-out area
-
working area
-
yard area
-
yoke area -
20 speed
2) частота вращения; число оборотов4) быстродействие || быстродействующий7) кфт. частота смены кадров8) светосила9) двигаться с большой скоростью, идти полным ходом•to speed up — 1. ускорять; разгонять 2. увеличивать частоту вращения или число оборотов 3. запускать-
above-synchronous speed
-
absolute speed
-
acoustic speed
-
actual speed
-
adjustable speed
-
advance speed
-
air speed
-
all engines speed
-
allowable speed
-
angular speed
-
approach speed
-
arc speed
-
armature speed
-
ASA speed
-
backing-out speed
-
blade speed
-
block speed
-
boring speed
-
boundary speed
-
breakdown speed
-
breaker speed
-
calm water speed
-
camera speed
-
cascading speed
-
circuit speed
-
circumferential speed
-
climbing speed
-
climb speed
-
closing speed
-
collecting speed
-
commercial speed
-
computation speed
-
computer speed
-
condenser speed
-
continuous cruising speed
-
control speed
-
conveying speed
-
copying speed
-
cranking speed
-
crawl speed
-
creep speed
-
creep-feed speed
-
critical buildup speed
-
critical speed
-
cruising speed
-
cutter feed speed
-
cutting speed
-
dead slow speed
-
dead speed
-
design speed
-
development speed
-
digging speed
-
drift speed
-
drilling speed
-
driving speed
-
economical speed
-
economic speed
-
emergency descent speed
-
emergency speed
-
emulsion speed
-
engine speed
-
fair speed
-
film speed
-
filming speed
-
finishing speed
-
flank speed
-
flitting speed
-
foilborne speed
-
forward speed
-
free-route speed
-
full speed
-
full-field speed
-
full-load speed
-
functional speed
-
gaging speed
-
gob speed
-
grinding speed
-
ground speed
-
half speed
-
head speed
-
headwheel speed
-
hull-borne speed
-
hump speed
-
hypersonic speed
-
idle speed
-
indexing speed
-
infinitely adjustable speed
-
input speed
-
instantaneous speed
-
landing approach speed
-
landing gear operating speed
-
landing speed
-
leading-in speed
-
lens speed
-
level-flight speed
-
light speed
-
line speed
-
linear speed
-
load speed
-
loaded speed
-
loading speed
-
low speed
-
machining speed
-
marker-horizon speed
-
marker speed
-
mean speed
-
milling speed
-
motor speed
-
movement speed
-
navigable speed
-
near-sonic speed
-
noload speed
-
nominal speed
-
normal speed
-
operating speed
-
operation speed
-
output speed
-
penetrating speed
-
peripheral speed
-
permanent noload speed
-
photographic speed
-
plowing speed
-
power-off speed
-
power-on speed
-
preset speed
-
press speed
-
primary draw-off speed
-
printout speed
-
process speed
-
projection speed
-
pulling speed
-
pump speed
-
rated speed
-
reading speed
-
reaming speed
-
recording speed
-
related speeds
-
relative speed
-
resonant speed
-
response speed
-
resultant speed
-
retraction speed
-
return speed
-
rig total operating speed
-
rim speed
-
robot speed
-
rod speed
-
rope speed
-
rotary speed
-
rotor speed
-
runaway speed
-
running speed
-
sawing speed
-
scanning speed
-
sea speed
-
service speed
-
shaft speed
-
shaper speed
-
shutter speed
-
sinking speed
-
slow speed
-
sonic speed
-
sound speed
-
specific speed
-
speed of discharge
-
speed of kiln
-
speed of loading
-
speed of photographic emulsion
-
speed of rotation
-
speed of wave propagation
-
spot speed
-
steady-flight speed
-
steady-state speed
-
stream speed
-
subsonic speed
-
supersonic speed
-
surface speed
-
sweep speed
-
swing speed
-
switching speed
-
synchronous speed
-
tailwind speed
-
take-home speed
-
takeoff speed
-
take-up speed
-
taking speed
-
tapping speed
-
threading speed
-
tip speed
-
tool-changing speed
-
top speed
-
touchdown speed
-
towing speed
-
tracing speed
-
tracking speed
-
track speed
-
transmission speed
-
transonic speed
-
traverse speed
-
trial-trip speed
-
trial speed
-
true ground speed
-
tunneling speed
-
turning speed
-
ultrasonic speed
-
variable speed
-
vertical gust speed
-
vertical speed
-
walking speed
-
water speed
-
wind speed
-
winding speed
-
wind-up speed
-
wire feed speed
-
wire speed
-
working speed
-
write speed
-
writing speed
-
zero speed
См. также в других словарях:
Critical taper — In mechanics and geodynamics, a critical taper is the equilibrium angle made by the far end of a wedge shaped agglomeration of material that is being pushed by the near end. The angle of the critical taper is a function of the material properties … Wikipedia
Total Maximum Daily Load — A Total Maximum Daily Load (TMDL) is a regulatory term in the U.S. Clean Water Act (CWA), describing a value of the maximum amount of a pollutant that a body of water can receive while still meeting water quality standards. [CWA sec. 303(d),… … Wikipedia
Load profile — In electrical engineering, a load profile is a graph of the variation in the electrical load versus time. A load profile will vary according to customer type (typical examples include residential, commercial and industrial), temperature and… … Wikipedia
Network Load Balancing — (commonly referred to as dual WAN routing or multihoming) is the ability to balance traffic across two WAN links without using complex routing protocols like BGP. This capability balances network sessions like Web, email, etc. over multiple… … Wikipedia
параллельная система ИБП — [Интент] Parallel Operation: The system shall have the option to install up to four (4) UPSs in parallel configuration for redundancy or capacity. 1. The parallel UPS system shall be of the same design, voltage, and frequency. UPS modules of… … Справочник технического переводчика
предельная нагрузка (выше которой алмазы разрушаются) — — [http://slovarionline.ru/anglo russkiy slovar neftegazovoy promyishlennosti/] Тематики нефтегазовая промышленность EN total critical loadtotal critical pressure … Справочник технического переводчика
environment — environmental, adj. environmentally, adv. /en vuy reuhn meuhnt, vuy euhrn /, n. 1. the aggregate of surrounding things, conditions, or influences; surroundings; milieu. 2. Ecol. the air, water, minerals, organisms, and all other external factors… … Universalium
physical science, principles of — Introduction the procedures and concepts employed by those who study the inorganic world. physical science, like all the natural sciences, is concerned with describing and relating to one another those experiences of the surrounding… … Universalium
river — river1 riverless, adj. riverlike, adj. /riv euhr/, n. 1. a natural stream of water of fairly large size flowing in a definite course or channel or series of diverging and converging channels. 2. a similar stream of something other than water: a… … Universalium
solids, mechanics of — ▪ physics Introduction science concerned with the stressing (stress), deformation (deformation and flow), and failure of solid materials and structures. What, then, is a solid? Any material, fluid or solid, can support normal forces.… … Universalium
Structural engineering — is a field of engineering dealing with the analysis and design of structures that support or resist loads. Structural engineering is usually considered a speciality within civil engineering, but it can also be studied in its own right. [cite… … Wikipedia